Minimal hypersurfaces and boundary behavior of compact manifolds with nonnegative scalar curvature

Abstract

On a compact Riemannian manifold with boundary having positive mean curvature, a fundamental result of Shi and Tam states that, if the manifold has nonnegative scalar curvature and if the boundary is isometric to a strictly convex hypersurface in the Euclidean space, then the total mean curvature of the boundary is no greater than the total mean curvature of the corresponding Euclidean hypersurface. In 3-dimension, Shi-Tam's result is known to be equivalent to the Riemannian positive mass theorem. In this paper, we provide a supplement to Shi-Tam's result by including the effect of minimal hypersurfaces on the boundary. More precisely, given a compact manifold with nonnegative scalar curvature, assuming its boundary consists of two parts, h and o, where h is the union of all closed minimal hypersurfaces in and o is isometric to a suitable 2-convex hypersurface in a spatial Schwarzschild manifold of positive mass m, we establish an inequality relating m, the area of h, and two weighted total mean curvatures of o and . In 3-dimension, the inequality has implications to both isometric embedding and quasi-local mass problems. In a relativistic context, our result can be interpreted as a quasi-local mass type quantity of o being greater than or equal to the Hawking mass of h. We further analyze the limit of such quasi-local mass quantity associated with suitably chosen isometric embeddings of large coordinate spheres of an asymptotically flat 3-manifold M into a spatial Schwarzschild manifold. We show that the limit equals the ADM mass of M. It follows that our result on the compact manifold is equivalent to the Riemannian Penrose inequality.